260 BIBLIOGRAPHY Phene, C. J., H<strong>of</strong>fm<strong>an</strong>, G. J. & Rawlins, S. L. (1971), ‘Measuring soil matric potential in situ by sensing heat dissipation with a porous body: Theory <strong>an</strong>d sensor contruction’, Soil Science Society <strong>of</strong> America Journal 35, 27–32. Philip, J. R. (1964), ‘Similarity hypothesis for capillary hysteresis in porous materials’, Journal <strong>of</strong> Geophysical Research 69, 1553–1562. Plagge, R., Häupl, P. & Renger, M. (1997), Tr<strong>an</strong>sient effects on the hydraulic properties <strong>of</strong> porous media, in F. J. L. M. Th. V<strong>an</strong> Genuchten & L. Wu, eds, ‘Proc. <strong>of</strong> the Int. Workshop on Characterization <strong>an</strong>d Measurement <strong>of</strong> the Hydraulic <strong>Properties</strong> <strong>of</strong> <strong>Unsaturated</strong> Porous Media’, University <strong>of</strong> California, Riverside, CA., pp. 905–912. Poulovassilis, A. (1962), ‘Hysteresis <strong>of</strong> pore water - An application <strong>of</strong> the concept <strong>of</strong> indepen- dent domains’, Soil Science 92, 405–412. Poulovassilis, A. (1969), ‘The effect <strong>of</strong> hysteresis <strong>of</strong> pore water on the hydraulic conductivity’, Journal <strong>of</strong> Soil Science 20(1), 52–56. Poulovassilis, A. (1970), ‘Hysteresis <strong>of</strong> pore water in gr<strong>an</strong>ular porous bodies’, Soil Science 109(1), 5–12. Poulovassilis, A. & El-Gharmy, W. M. (1978), ‘The dependent domain theory applied to sc<strong>an</strong>ning curves <strong>of</strong> <strong>an</strong>y order in hysteretic soil water relationship’, Journal <strong>of</strong> Soil Science 126, 1–8. Pr<strong>an</strong>dtl, L. (1921), ‘Eindringungsfestigkeit und Festigkeit von Schneiden’, Zeitschrift für Angew<strong>an</strong>dte Mathematik und Mech<strong>an</strong>ik 1(4), 15–20. Rahardjo, H. & Fredlund, D. G. (2003), ‘Ko-volume ch<strong>an</strong>ge charactersitics <strong>of</strong> <strong>an</strong> unsaturated soil with respect to various loading paths’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 26(1), 1–11. Rampino, C., M<strong>an</strong>cuso, C. & Vinale, F. (1999), ‘Laboratory testing on <strong>an</strong> unsaturated soil: equipment, procedures, <strong>an</strong>d first experimental results’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 36, 1–12. Rampino, C., M<strong>an</strong>cuso, C. & Vinale, F. (2000), ‘Experimental behavior <strong>an</strong>g modelling <strong>of</strong> <strong>an</strong> unsaturated compacted soil’, C<strong>an</strong>adi<strong>an</strong> Geotechnical Journal 37, 748–763. Reeve, M. J., Smith, P. D. & Thomasson, A. J. (1973), ‘The effect <strong>of</strong> density on water retention properties <strong>of</strong> field soils’, Journal <strong>of</strong> Soil Science 24(3), 355–367. Reginato, R. J. & v<strong>an</strong> Bavel, C. H. M. (1962), ‘Pressure cell for soil cores’, Soil Science Society <strong>of</strong> America Journal 26, 1–3. Rendulic, L. (1936), Relation between void ratio <strong>an</strong>d effective principles stresses for a re- moulded silty clay, in ‘1st Int. Conf. Soil Mech. Found. Eng.’, Cambridge, MA, pp. 48–51.
BIBLIOGRAPHY 261 Reynolds, W. & Elrick, D. (1991), ‘Determination <strong>of</strong> hydraulic conductivity using a tension infiltrometer’, Soil Science Society <strong>of</strong> America Journal 55, 633–639. Richards, L. A. (1928), ‘The usefulness <strong>of</strong> capillary potential to soil moisture <strong>an</strong>d pl<strong>an</strong>t in- vestigators’, Journal <strong>of</strong> Agricultural Research 37, 719–742. Richards, L. A. (1931), ‘Capillary conduction <strong>of</strong> liquids thgrough porous medium’, Physics 1, 318–333. Richards, L. A. (1941), ‘A pressure-membr<strong>an</strong>e extraction apparatus for soil solution’, Soil Science 51, 377–386. Richards, L. A. (1947), ‘Pressure-membr<strong>an</strong>e apparatus - constrution <strong>an</strong>d use’, Agricultural Engineering 28, 451–454. Richards, L. A. & Weaver, L. R. (1944), ‘Moisture retention by some irrigated soils related to soil moisture tension’, Journal <strong>of</strong> Agricultural Research 69, 215–235. Richards, S. & Weeks, L. (1953), ‘Capillary conductivity values from moisture yield <strong>an</strong>d tension measurements on soil columns’, Soil Science Society <strong>of</strong> America Journal 55, 206– 209. Ridley, A. M. & Burl<strong>an</strong>d, J. B. (1993), ‘A new instrument for the measurement <strong>of</strong> soil suction’, Géotechnique 43(2), 321–324. Ridley, A. M. & Wray, W. K. (1996), Suction measurement: A review <strong>of</strong> current theory <strong>an</strong>d practices, in E. E. Alonso & P. Delage, eds, ‘1st International Conference on <strong>Unsaturated</strong> Soils (UNSAT 95)’, Balkema, Rotterdam, Paris, pp. 1293–1322. Robinson, D. A., Gardner, C. M. K., Ev<strong>an</strong>s, J., Cooper, J. D., Hodnett, M. G. & Bell, J. P. (1998), ‘The dielectric calibration <strong>of</strong> capacit<strong>an</strong>ce probes for soil hydrology using <strong>an</strong> oscillation frequency response mode’, <strong>Hydro</strong>logy <strong>an</strong>d Earth System Sciences (2), 83–92. Robinson, D. A., Jones, S. B., Wraith, J. M., Or, D. & Freidm<strong>an</strong>, S. P. (2003), ‘A review <strong>of</strong> adv<strong>an</strong>ce s in dielctric <strong>an</strong>d electrical conductivity measurements in soils using time domain reflectometry’, Vadose Zone Journal 2, 444–475. Rogers, J. S. & Klute, A. (1971), ‘The hydraulic conductivity-water content relationship during nonsteady flow through a s<strong>an</strong>d column’, Soil Science Society <strong>of</strong> America Journal 35, 695–700. Rojas, E. & Rojas, F. (2005), ‘Modeling hysteresis <strong>of</strong> the soil-water characteristic curve’, Jap<strong>an</strong>ese Geotechnical Society 45(3), 135–145.
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Hydro-Mechanical Properties of Part
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